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linux/drivers/video/uvesafb.c

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uvesafb: the driver core uvesafb is an enhanced version of vesafb. It uses a userspace helper (v86d) to execute calls to the x86 Video BIOS functions. The driver is not limited to any specific arch and whether it works on a given arch or not depends on that arch being supported by the userspace daemon. It has been tested on x86_32 and x86_64. A single BIOS call is represented by an instance of the uvesafb_ktask structure. This structure contains a buffer, a completion struct and a uvesafb_task substructure, containing the values of the x86 registers, a flags field and a field indicating the length of the buffer. Whenever a BIOS call is made in the driver, uvesafb_exec() builds a message using the uvesafb_task substructure and the contents of the buffer. This message is then assigned a random ack number and sent to the userspace daemon using the connector interface. The message's sequence number is used as an index for the uvfb_tasks array, which provides a mapping from the messages coming from userspace to the in-kernel uvesafb_ktask structs. The userspace daemon performs the requested operation and sends a reply in the form of a uvesafb_task struct and, optionally, a buffer. The seq and ack numbers in the reply should be exactly the same as those in the request. Each message from userspace is processed by uvesafb_cn_callback() and after passing a few sanity checks leads to the completion of a BIOS call request. Signed-off-by: Michal Januszewski <spock@gentoo.org> Signed-off-by: Antonino Daplas <adaplas@gmail.com> Cc: Paul Mundt <lethal@linux-sh.org> Cc: Paulo Marques <pmarques@grupopie.com> Cc: "H. Peter Anvin" <hpa@zytor.com> Signed-off-by: Andrew Morton <akpm@linux-foundation.org> Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
2007-10-16 01:28:26 -07:00
/*
* A framebuffer driver for VBE 2.0+ compliant video cards
*
* (c) 2007 Michal Januszewski <spock@gentoo.org>
* Loosely based upon the vesafb driver.
*
*/
#include <linux/init.h>
#include <linux/module.h>
#include <linux/moduleparam.h>
#include <linux/skbuff.h>
#include <linux/timer.h>
#include <linux/completion.h>
#include <linux/connector.h>
#include <linux/random.h>
#include <linux/platform_device.h>
#include <linux/limits.h>
#include <linux/fb.h>
#include <linux/io.h>
#include <linux/mutex.h>
#include <video/edid.h>
#include <video/uvesafb.h>
#ifdef CONFIG_X86
#include <video/vga.h>
#endif
#ifdef CONFIG_MTRR
#include <asm/mtrr.h>
#endif
#include "edid.h"
static struct cb_id uvesafb_cn_id = {
.idx = CN_IDX_V86D,
.val = CN_VAL_V86D_UVESAFB
};
static char v86d_path[PATH_MAX] = "/sbin/v86d";
static char v86d_started; /* has v86d been started by uvesafb? */
static struct fb_fix_screeninfo uvesafb_fix __devinitdata = {
.id = "VESA VGA",
.type = FB_TYPE_PACKED_PIXELS,
.accel = FB_ACCEL_NONE,
.visual = FB_VISUAL_TRUECOLOR,
};
static int mtrr __devinitdata = 3; /* enable mtrr by default */
static int blank = 1; /* enable blanking by default */
uvesafb: the driver core uvesafb is an enhanced version of vesafb. It uses a userspace helper (v86d) to execute calls to the x86 Video BIOS functions. The driver is not limited to any specific arch and whether it works on a given arch or not depends on that arch being supported by the userspace daemon. It has been tested on x86_32 and x86_64. A single BIOS call is represented by an instance of the uvesafb_ktask structure. This structure contains a buffer, a completion struct and a uvesafb_task substructure, containing the values of the x86 registers, a flags field and a field indicating the length of the buffer. Whenever a BIOS call is made in the driver, uvesafb_exec() builds a message using the uvesafb_task substructure and the contents of the buffer. This message is then assigned a random ack number and sent to the userspace daemon using the connector interface. The message's sequence number is used as an index for the uvfb_tasks array, which provides a mapping from the messages coming from userspace to the in-kernel uvesafb_ktask structs. The userspace daemon performs the requested operation and sends a reply in the form of a uvesafb_task struct and, optionally, a buffer. The seq and ack numbers in the reply should be exactly the same as those in the request. Each message from userspace is processed by uvesafb_cn_callback() and after passing a few sanity checks leads to the completion of a BIOS call request. Signed-off-by: Michal Januszewski <spock@gentoo.org> Signed-off-by: Antonino Daplas <adaplas@gmail.com> Cc: Paul Mundt <lethal@linux-sh.org> Cc: Paulo Marques <pmarques@grupopie.com> Cc: "H. Peter Anvin" <hpa@zytor.com> Signed-off-by: Andrew Morton <akpm@linux-foundation.org> Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
2007-10-16 01:28:26 -07:00
static int ypan __devinitdata = 1; /* 0: scroll, 1: ypan, 2: ywrap */
static int pmi_setpal __devinitdata = 1; /* use PMI for palette changes */
static int nocrtc __devinitdata; /* ignore CRTC settings */
static int noedid __devinitdata; /* don't try DDC transfers */
static int vram_remap __devinitdata; /* set amt. of memory to be used */
static int vram_total __devinitdata; /* set total amount of memory */
static u16 maxclk __devinitdata; /* maximum pixel clock */
static u16 maxvf __devinitdata; /* maximum vertical frequency */
static u16 maxhf __devinitdata; /* maximum horizontal frequency */
static u16 vbemode __devinitdata; /* force use of a specific VBE mode */
static char *mode_option __devinitdata;
static struct uvesafb_ktask *uvfb_tasks[UVESAFB_TASKS_MAX];
static DEFINE_MUTEX(uvfb_lock);
/*
* A handler for replies from userspace.
*
* Make sure each message passes consistency checks and if it does,
* find the kernel part of the task struct, copy the registers and
* the buffer contents and then complete the task.
*/
static void uvesafb_cn_callback(void *data)
{
struct cn_msg *msg = data;
struct uvesafb_task *utask;
struct uvesafb_ktask *task;
if (msg->seq >= UVESAFB_TASKS_MAX)
return;
mutex_lock(&uvfb_lock);
task = uvfb_tasks[msg->seq];
if (!task || msg->ack != task->ack) {
mutex_unlock(&uvfb_lock);
return;
}
utask = (struct uvesafb_task *)msg->data;
/* Sanity checks for the buffer length. */
if (task->t.buf_len < utask->buf_len ||
utask->buf_len > msg->len - sizeof(*utask)) {
mutex_unlock(&uvfb_lock);
return;
}
uvfb_tasks[msg->seq] = NULL;
mutex_unlock(&uvfb_lock);
memcpy(&task->t, utask, sizeof(*utask));
if (task->t.buf_len && task->buf)
memcpy(task->buf, utask + 1, task->t.buf_len);
complete(task->done);
return;
}
static int uvesafb_helper_start(void)
{
char *envp[] = {
"HOME=/",
"PATH=/sbin:/bin",
NULL,
};
char *argv[] = {
v86d_path,
NULL,
};
return call_usermodehelper(v86d_path, argv, envp, 1);
}
/*
* Execute a uvesafb task.
*
* Returns 0 if the task is executed successfully.
*
* A message sent to the userspace consists of the uvesafb_task
* struct and (optionally) a buffer. The uvesafb_task struct is
* a simplified version of uvesafb_ktask (its kernel counterpart)
* containing only the register values, flags and the length of
* the buffer.
*
* Each message is assigned a sequence number (increased linearly)
* and a random ack number. The sequence number is used as a key
* for the uvfb_tasks array which holds pointers to uvesafb_ktask
* structs for all requests.
*/
static int uvesafb_exec(struct uvesafb_ktask *task)
{
static int seq;
struct cn_msg *m;
int err;
int len = sizeof(task->t) + task->t.buf_len;
/*
* Check whether the message isn't longer than the maximum
* allowed by connector.
*/
if (sizeof(*m) + len > CONNECTOR_MAX_MSG_SIZE) {
printk(KERN_WARNING "uvesafb: message too long (%d), "
"can't execute task\n", (int)(sizeof(*m) + len));
return -E2BIG;
}
m = kzalloc(sizeof(*m) + len, GFP_KERNEL);
if (!m)
return -ENOMEM;
init_completion(task->done);
memcpy(&m->id, &uvesafb_cn_id, sizeof(m->id));
m->seq = seq;
m->len = len;
m->ack = random32();
/* uvesafb_task structure */
memcpy(m + 1, &task->t, sizeof(task->t));
/* Buffer */
memcpy((u8 *)(m + 1) + sizeof(task->t), task->buf, task->t.buf_len);
/*
* Save the message ack number so that we can find the kernel
* part of this task when a reply is received from userspace.
*/
task->ack = m->ack;
mutex_lock(&uvfb_lock);
/* If all slots are taken -- bail out. */
if (uvfb_tasks[seq]) {
mutex_unlock(&uvfb_lock);
return -EBUSY;
}
/* Save a pointer to the kernel part of the task struct. */
uvfb_tasks[seq] = task;
mutex_unlock(&uvfb_lock);
err = cn_netlink_send(m, 0, gfp_any());
if (err == -ESRCH) {
/*
* Try to start the userspace helper if sending
* the request failed the first time.
*/
err = uvesafb_helper_start();
if (err) {
printk(KERN_ERR "uvesafb: failed to execute %s\n",
v86d_path);
printk(KERN_ERR "uvesafb: make sure that the v86d "
"helper is installed and executable\n");
} else {
v86d_started = 1;
err = cn_netlink_send(m, 0, gfp_any());
}
}
kfree(m);
if (!err && !(task->t.flags & TF_EXIT))
err = !wait_for_completion_timeout(task->done,
msecs_to_jiffies(UVESAFB_TIMEOUT));
mutex_lock(&uvfb_lock);
uvfb_tasks[seq] = NULL;
mutex_unlock(&uvfb_lock);
seq++;
if (seq >= UVESAFB_TASKS_MAX)
seq = 0;
return err;
}
/*
* Free a uvesafb_ktask struct.
*/
static void uvesafb_free(struct uvesafb_ktask *task)
{
if (task) {
if (task->done)
kfree(task->done);
kfree(task);
}
}
/*
* Prepare a uvesafb_ktask struct to be used again.
*/
static void uvesafb_reset(struct uvesafb_ktask *task)
{
struct completion *cpl = task->done;
memset(task, 0, sizeof(*task));
task->done = cpl;
}
/*
* Allocate and prepare a uvesafb_ktask struct.
*/
static struct uvesafb_ktask *uvesafb_prep(void)
{
struct uvesafb_ktask *task;
task = kzalloc(sizeof(*task), GFP_KERNEL);
if (task) {
task->done = kzalloc(sizeof(*task->done), GFP_KERNEL);
if (!task->done) {
kfree(task);
task = NULL;
}
}
return task;
}
static void uvesafb_setup_var(struct fb_var_screeninfo *var,
struct fb_info *info, struct vbe_mode_ib *mode)
{
struct uvesafb_par *par = info->par;
var->vmode = FB_VMODE_NONINTERLACED;
var->sync = FB_SYNC_VERT_HIGH_ACT;
var->xres = mode->x_res;
var->yres = mode->y_res;
var->xres_virtual = mode->x_res;
var->yres_virtual = (par->ypan) ?
info->fix.smem_len / mode->bytes_per_scan_line :
mode->y_res;
var->xoffset = 0;
var->yoffset = 0;
var->bits_per_pixel = mode->bits_per_pixel;
if (var->bits_per_pixel == 15)
var->bits_per_pixel = 16;
if (var->bits_per_pixel > 8) {
var->red.offset = mode->red_off;
var->red.length = mode->red_len;
var->green.offset = mode->green_off;
var->green.length = mode->green_len;
var->blue.offset = mode->blue_off;
var->blue.length = mode->blue_len;
var->transp.offset = mode->rsvd_off;
var->transp.length = mode->rsvd_len;
} else {
var->red.offset = 0;
var->green.offset = 0;
var->blue.offset = 0;
var->transp.offset = 0;
/*
* We're assuming that we can switch the DAC to 8 bits. If
* this proves to be incorrect, we'll update the fields
* later in set_par().
*/
if (par->vbe_ib.capabilities & VBE_CAP_CAN_SWITCH_DAC) {
var->red.length = 8;
var->green.length = 8;
var->blue.length = 8;
var->transp.length = 0;
} else {
var->red.length = 6;
var->green.length = 6;
var->blue.length = 6;
var->transp.length = 0;
}
}
}
static int uvesafb_vbe_find_mode(struct uvesafb_par *par,
int xres, int yres, int depth, unsigned char flags)
{
int i, match = -1, h = 0, d = 0x7fffffff;
for (i = 0; i < par->vbe_modes_cnt; i++) {
h = abs(par->vbe_modes[i].x_res - xres) +
abs(par->vbe_modes[i].y_res - yres) +
abs(depth - par->vbe_modes[i].depth);
/*
* We have an exact match in terms of resolution
* and depth.
*/
if (h == 0)
return i;
if (h < d || (h == d && par->vbe_modes[i].depth > depth)) {
d = h;
match = i;
}
}
i = 1;
if (flags & UVESAFB_EXACT_DEPTH &&
par->vbe_modes[match].depth != depth)
i = 0;
if (flags & UVESAFB_EXACT_RES && d > 24)
i = 0;
if (i != 0)
return match;
else
return -1;
}
static u8 *uvesafb_vbe_state_save(struct uvesafb_par *par)
{
struct uvesafb_ktask *task;
u8 *state;
int err;
if (!par->vbe_state_size)
return NULL;
state = kmalloc(par->vbe_state_size, GFP_KERNEL);
if (!state)
return NULL;
task = uvesafb_prep();
if (!task) {
kfree(state);
return NULL;
}
task->t.regs.eax = 0x4f04;
task->t.regs.ecx = 0x000f;
task->t.regs.edx = 0x0001;
task->t.flags = TF_BUF_RET | TF_BUF_ESBX;
task->t.buf_len = par->vbe_state_size;
task->buf = state;
err = uvesafb_exec(task);
if (err || (task->t.regs.eax & 0xffff) != 0x004f) {
printk(KERN_WARNING "uvesafb: VBE get state call "
"failed (eax=0x%x, err=%d)\n",
task->t.regs.eax, err);
kfree(state);
state = NULL;
}
uvesafb_free(task);
return state;
}
static void uvesafb_vbe_state_restore(struct uvesafb_par *par, u8 *state_buf)
{
struct uvesafb_ktask *task;
int err;
if (!state_buf)
return;
task = uvesafb_prep();
if (!task)
return;
task->t.regs.eax = 0x4f04;
task->t.regs.ecx = 0x000f;
task->t.regs.edx = 0x0002;
task->t.buf_len = par->vbe_state_size;
task->t.flags = TF_BUF_ESBX;
task->buf = state_buf;
err = uvesafb_exec(task);
if (err || (task->t.regs.eax & 0xffff) != 0x004f)
printk(KERN_WARNING "uvesafb: VBE state restore call "
"failed (eax=0x%x, err=%d)\n",
task->t.regs.eax, err);
uvesafb_free(task);
}
static int __devinit uvesafb_vbe_getinfo(struct uvesafb_ktask *task,
struct uvesafb_par *par)
{
int err;
task->t.regs.eax = 0x4f00;
task->t.flags = TF_VBEIB;
task->t.buf_len = sizeof(struct vbe_ib);
task->buf = &par->vbe_ib;
strncpy(par->vbe_ib.vbe_signature, "VBE2", 4);
err = uvesafb_exec(task);
if (err || (task->t.regs.eax & 0xffff) != 0x004f) {
printk(KERN_ERR "uvesafb: Getting VBE info block failed "
"(eax=0x%x, err=%d)\n", (u32)task->t.regs.eax,
err);
return -EINVAL;
}
if (par->vbe_ib.vbe_version < 0x0200) {
printk(KERN_ERR "uvesafb: Sorry, pre-VBE 2.0 cards are "
"not supported.\n");
return -EINVAL;
}
if (!par->vbe_ib.mode_list_ptr) {
printk(KERN_ERR "uvesafb: Missing mode list!\n");
return -EINVAL;
}
printk(KERN_INFO "uvesafb: ");
/*
* Convert string pointers and the mode list pointer into
* usable addresses. Print informational messages about the
* video adapter and its vendor.
*/
if (par->vbe_ib.oem_vendor_name_ptr)
printk("%s, ",
((char *)task->buf) + par->vbe_ib.oem_vendor_name_ptr);
if (par->vbe_ib.oem_product_name_ptr)
printk("%s, ",
((char *)task->buf) + par->vbe_ib.oem_product_name_ptr);
if (par->vbe_ib.oem_product_rev_ptr)
printk("%s, ",
((char *)task->buf) + par->vbe_ib.oem_product_rev_ptr);
if (par->vbe_ib.oem_string_ptr)
printk("OEM: %s, ",
((char *)task->buf) + par->vbe_ib.oem_string_ptr);
printk("VBE v%d.%d\n", ((par->vbe_ib.vbe_version & 0xff00) >> 8),
par->vbe_ib.vbe_version & 0xff);
return 0;
}
static int __devinit uvesafb_vbe_getmodes(struct uvesafb_ktask *task,
struct uvesafb_par *par)
{
int off = 0, err;
u16 *mode;
par->vbe_modes_cnt = 0;
/* Count available modes. */
mode = (u16 *) (((u8 *)&par->vbe_ib) + par->vbe_ib.mode_list_ptr);
while (*mode != 0xffff) {
par->vbe_modes_cnt++;
mode++;
}
par->vbe_modes = kzalloc(sizeof(struct vbe_mode_ib) *
par->vbe_modes_cnt, GFP_KERNEL);
if (!par->vbe_modes)
return -ENOMEM;
/* Get info about all available modes. */
mode = (u16 *) (((u8 *)&par->vbe_ib) + par->vbe_ib.mode_list_ptr);
while (*mode != 0xffff) {
struct vbe_mode_ib *mib;
uvesafb_reset(task);
task->t.regs.eax = 0x4f01;
task->t.regs.ecx = (u32) *mode;
task->t.flags = TF_BUF_RET | TF_BUF_ESDI;
task->t.buf_len = sizeof(struct vbe_mode_ib);
task->buf = par->vbe_modes + off;
err = uvesafb_exec(task);
if (err || (task->t.regs.eax & 0xffff) != 0x004f) {
printk(KERN_ERR "uvesafb: Getting mode info block "
"for mode 0x%x failed (eax=0x%x, err=%d)\n",
*mode, (u32)task->t.regs.eax, err);
return -EINVAL;
}
mib = task->buf;
mib->mode_id = *mode;
/*
* We only want modes that are supported with the current
* hardware configuration, color, graphics and that have
* support for the LFB.
*/
if ((mib->mode_attr & VBE_MODE_MASK) == VBE_MODE_MASK &&
mib->bits_per_pixel >= 8)
off++;
else
par->vbe_modes_cnt--;
mode++;
mib->depth = mib->red_len + mib->green_len + mib->blue_len;
/*
* Handle 8bpp modes and modes with broken color component
* lengths.
*/
if (mib->depth == 0 || (mib->depth == 24 &&
mib->bits_per_pixel == 32))
mib->depth = mib->bits_per_pixel;
}
return 0;
}
/*
* The Protected Mode Interface is 32-bit x86 code, so we only run it on
* x86 and not x86_64.
*/
#ifdef CONFIG_X86_32
static int __devinit uvesafb_vbe_getpmi(struct uvesafb_ktask *task,
struct uvesafb_par *par)
{
int i, err;
uvesafb_reset(task);
task->t.regs.eax = 0x4f0a;
task->t.regs.ebx = 0x0;
err = uvesafb_exec(task);
if ((task->t.regs.eax & 0xffff) != 0x4f || task->t.regs.es < 0xc000) {
par->pmi_setpal = par->ypan = 0;
} else {
par->pmi_base = (u16 *)phys_to_virt(((u32)task->t.regs.es << 4)
+ task->t.regs.edi);
par->pmi_start = (u8 *)par->pmi_base + par->pmi_base[1];
par->pmi_pal = (u8 *)par->pmi_base + par->pmi_base[2];
printk(KERN_INFO "uvesafb: protected mode interface info at "
"%04x:%04x\n",
(u16)task->t.regs.es, (u16)task->t.regs.edi);
printk(KERN_INFO "uvesafb: pmi: set display start = %p, "
"set palette = %p\n", par->pmi_start,
par->pmi_pal);
if (par->pmi_base[3]) {
printk(KERN_INFO "uvesafb: pmi: ports = ");
for (i = par->pmi_base[3]/2;
par->pmi_base[i] != 0xffff; i++)
printk("%x ", par->pmi_base[i]);
printk("\n");
if (par->pmi_base[i] != 0xffff) {
printk(KERN_INFO "uvesafb: can't handle memory"
" requests, pmi disabled\n");
par->ypan = par->pmi_setpal = 0;
}
}
}
return 0;
}
#endif /* CONFIG_X86_32 */
/*
* Check whether a video mode is supported by the Video BIOS and is
* compatible with the monitor limits.
*/
static int __devinit uvesafb_is_valid_mode(struct fb_videomode *mode,
struct fb_info *info)
{
if (info->monspecs.gtf) {
fb_videomode_to_var(&info->var, mode);
if (fb_validate_mode(&info->var, info))
return 0;
}
if (uvesafb_vbe_find_mode(info->par, mode->xres, mode->yres, 8,
UVESAFB_EXACT_RES) == -1)
return 0;
return 1;
}
static int __devinit uvesafb_vbe_getedid(struct uvesafb_ktask *task,
struct fb_info *info)
{
struct uvesafb_par *par = info->par;
int err = 0;
if (noedid || par->vbe_ib.vbe_version < 0x0300)
return -EINVAL;
task->t.regs.eax = 0x4f15;
task->t.regs.ebx = 0;
task->t.regs.ecx = 0;
task->t.buf_len = 0;
task->t.flags = 0;
err = uvesafb_exec(task);
if ((task->t.regs.eax & 0xffff) != 0x004f || err)
return -EINVAL;
if ((task->t.regs.ebx & 0x3) == 3) {
printk(KERN_INFO "uvesafb: VBIOS/hardware supports both "
"DDC1 and DDC2 transfers\n");
} else if ((task->t.regs.ebx & 0x3) == 2) {
printk(KERN_INFO "uvesafb: VBIOS/hardware supports DDC2 "
"transfers\n");
} else if ((task->t.regs.ebx & 0x3) == 1) {
printk(KERN_INFO "uvesafb: VBIOS/hardware supports DDC1 "
"transfers\n");
} else {
printk(KERN_INFO "uvesafb: VBIOS/hardware doesn't support "
"DDC transfers\n");
return -EINVAL;
}
task->t.regs.eax = 0x4f15;
task->t.regs.ebx = 1;
task->t.regs.ecx = task->t.regs.edx = 0;
task->t.flags = TF_BUF_RET | TF_BUF_ESDI;
task->t.buf_len = EDID_LENGTH;
task->buf = kzalloc(EDID_LENGTH, GFP_KERNEL);
err = uvesafb_exec(task);
if ((task->t.regs.eax & 0xffff) == 0x004f && !err) {
fb_edid_to_monspecs(task->buf, &info->monspecs);
if (info->monspecs.vfmax && info->monspecs.hfmax) {
/*
* If the maximum pixel clock wasn't specified in
* the EDID block, set it to 300 MHz.
*/
if (info->monspecs.dclkmax == 0)
info->monspecs.dclkmax = 300 * 1000000;
info->monspecs.gtf = 1;
}
} else {
err = -EINVAL;
}
kfree(task->buf);
return err;
}
static void __devinit uvesafb_vbe_getmonspecs(struct uvesafb_ktask *task,
struct fb_info *info)
{
struct uvesafb_par *par = info->par;
int i;
memset(&info->monspecs, 0, sizeof(info->monspecs));
/*
* If we don't get all necessary data from the EDID block,
* mark it as incompatible with the GTF and set nocrtc so
* that we always use the default BIOS refresh rate.
*/
if (uvesafb_vbe_getedid(task, info)) {
info->monspecs.gtf = 0;
par->nocrtc = 1;
}
/* Kernel command line overrides. */
if (maxclk)
info->monspecs.dclkmax = maxclk * 1000000;
if (maxvf)
info->monspecs.vfmax = maxvf;
if (maxhf)
info->monspecs.hfmax = maxhf * 1000;
/*
* In case DDC transfers are not supported, the user can provide
* monitor limits manually. Lower limits are set to "safe" values.
*/
if (info->monspecs.gtf == 0 && maxclk && maxvf && maxhf) {
info->monspecs.dclkmin = 0;
info->monspecs.vfmin = 60;
info->monspecs.hfmin = 29000;
info->monspecs.gtf = 1;
par->nocrtc = 0;
}
if (info->monspecs.gtf)
printk(KERN_INFO
"uvesafb: monitor limits: vf = %d Hz, hf = %d kHz, "
"clk = %d MHz\n", info->monspecs.vfmax,
(int)(info->monspecs.hfmax / 1000),
(int)(info->monspecs.dclkmax / 1000000));
else
printk(KERN_INFO "uvesafb: no monitor limits have been set, "
"default refresh rate will be used\n");
/* Add VBE modes to the modelist. */
for (i = 0; i < par->vbe_modes_cnt; i++) {
struct fb_var_screeninfo var;
struct vbe_mode_ib *mode;
struct fb_videomode vmode;
mode = &par->vbe_modes[i];
memset(&var, 0, sizeof(var));
var.xres = mode->x_res;
var.yres = mode->y_res;
fb_get_mode(FB_VSYNCTIMINGS | FB_IGNOREMON, 60, &var, info);
fb_var_to_videomode(&vmode, &var);
fb_add_videomode(&vmode, &info->modelist);
}
/* Add valid VESA modes to our modelist. */
for (i = 0; i < VESA_MODEDB_SIZE; i++) {
if (uvesafb_is_valid_mode((struct fb_videomode *)
&vesa_modes[i], info))
fb_add_videomode(&vesa_modes[i], &info->modelist);
}
for (i = 0; i < info->monspecs.modedb_len; i++) {
if (uvesafb_is_valid_mode(&info->monspecs.modedb[i], info))
fb_add_videomode(&info->monspecs.modedb[i],
&info->modelist);
}
return;
}
static void __devinit uvesafb_vbe_getstatesize(struct uvesafb_ktask *task,
struct uvesafb_par *par)
{
int err;
uvesafb_reset(task);
/*
* Get the VBE state buffer size. We want all available
* hardware state data (CL = 0x0f).
*/
task->t.regs.eax = 0x4f04;
task->t.regs.ecx = 0x000f;
task->t.regs.edx = 0x0000;
task->t.flags = 0;
err = uvesafb_exec(task);
if (err || (task->t.regs.eax & 0xffff) != 0x004f) {
printk(KERN_WARNING "uvesafb: VBE state buffer size "
"cannot be determined (eax=0x%x, err=%d)\n",
task->t.regs.eax, err);
par->vbe_state_size = 0;
return;
}
par->vbe_state_size = 64 * (task->t.regs.ebx & 0xffff);
}
static int __devinit uvesafb_vbe_init(struct fb_info *info)
{
struct uvesafb_ktask *task = NULL;
struct uvesafb_par *par = info->par;
int err;
task = uvesafb_prep();
if (!task)
return -ENOMEM;
err = uvesafb_vbe_getinfo(task, par);
if (err)
goto out;
err = uvesafb_vbe_getmodes(task, par);
if (err)
goto out;
par->nocrtc = nocrtc;
#ifdef CONFIG_X86_32
par->pmi_setpal = pmi_setpal;
par->ypan = ypan;
if (par->pmi_setpal || par->ypan)
uvesafb_vbe_getpmi(task, par);
#else
/* The protected mode interface is not available on non-x86. */
par->pmi_setpal = par->ypan = 0;
#endif
INIT_LIST_HEAD(&info->modelist);
uvesafb_vbe_getmonspecs(task, info);
uvesafb_vbe_getstatesize(task, par);
out: uvesafb_free(task);
return err;
}
static int __devinit uvesafb_vbe_init_mode(struct fb_info *info)
{
struct list_head *pos;
struct fb_modelist *modelist;
struct fb_videomode *mode;
struct uvesafb_par *par = info->par;
int i, modeid;
/* Has the user requested a specific VESA mode? */
if (vbemode) {
for (i = 0; i < par->vbe_modes_cnt; i++) {
if (par->vbe_modes[i].mode_id == vbemode) {
fb_get_mode(FB_VSYNCTIMINGS | FB_IGNOREMON, 60,
&info->var, info);
/*
* With pixclock set to 0, the default BIOS
* timings will be used in set_par().
*/
info->var.pixclock = 0;
modeid = i;
goto gotmode;
}
}
printk(KERN_INFO "uvesafb: requested VBE mode 0x%x is "
"unavailable\n", vbemode);
vbemode = 0;
}
/* Count the modes in the modelist */
i = 0;
list_for_each(pos, &info->modelist)
i++;
/*
* Convert the modelist into a modedb so that we can use it with
* fb_find_mode().
*/
mode = kzalloc(i * sizeof(*mode), GFP_KERNEL);
if (mode) {
i = 0;
list_for_each(pos, &info->modelist) {
modelist = list_entry(pos, struct fb_modelist, list);
mode[i] = modelist->mode;
i++;
}
if (!mode_option)
mode_option = UVESAFB_DEFAULT_MODE;
i = fb_find_mode(&info->var, info, mode_option, mode, i,
NULL, 8);
kfree(mode);
}
/* fb_find_mode() failed */
if (i == 0 || i >= 3) {
info->var.xres = 640;
info->var.yres = 480;
mode = (struct fb_videomode *)
fb_find_best_mode(&info->var, &info->modelist);
if (mode) {
fb_videomode_to_var(&info->var, mode);
} else {
modeid = par->vbe_modes[0].mode_id;
fb_get_mode(FB_VSYNCTIMINGS | FB_IGNOREMON, 60,
&info->var, info);
goto gotmode;
}
}
/* Look for a matching VBE mode. */
modeid = uvesafb_vbe_find_mode(par, info->var.xres, info->var.yres,
info->var.bits_per_pixel, UVESAFB_EXACT_RES);
if (modeid == -1)
return -EINVAL;
gotmode:
uvesafb_setup_var(&info->var, info, &par->vbe_modes[modeid]);
/*
* If we are not VBE3.0+ compliant, we're done -- the BIOS will
* ignore our timings anyway.
*/
if (par->vbe_ib.vbe_version < 0x0300 || par->nocrtc)
fb_get_mode(FB_VSYNCTIMINGS | FB_IGNOREMON, 60,
&info->var, info);
return modeid;
}
static int uvesafb_setpalette(struct uvesafb_pal_entry *entries, int count,
int start, struct fb_info *info)
{
struct uvesafb_ktask *task;
#ifdef CONFIG_X86
uvesafb: the driver core uvesafb is an enhanced version of vesafb. It uses a userspace helper (v86d) to execute calls to the x86 Video BIOS functions. The driver is not limited to any specific arch and whether it works on a given arch or not depends on that arch being supported by the userspace daemon. It has been tested on x86_32 and x86_64. A single BIOS call is represented by an instance of the uvesafb_ktask structure. This structure contains a buffer, a completion struct and a uvesafb_task substructure, containing the values of the x86 registers, a flags field and a field indicating the length of the buffer. Whenever a BIOS call is made in the driver, uvesafb_exec() builds a message using the uvesafb_task substructure and the contents of the buffer. This message is then assigned a random ack number and sent to the userspace daemon using the connector interface. The message's sequence number is used as an index for the uvfb_tasks array, which provides a mapping from the messages coming from userspace to the in-kernel uvesafb_ktask structs. The userspace daemon performs the requested operation and sends a reply in the form of a uvesafb_task struct and, optionally, a buffer. The seq and ack numbers in the reply should be exactly the same as those in the request. Each message from userspace is processed by uvesafb_cn_callback() and after passing a few sanity checks leads to the completion of a BIOS call request. Signed-off-by: Michal Januszewski <spock@gentoo.org> Signed-off-by: Antonino Daplas <adaplas@gmail.com> Cc: Paul Mundt <lethal@linux-sh.org> Cc: Paulo Marques <pmarques@grupopie.com> Cc: "H. Peter Anvin" <hpa@zytor.com> Signed-off-by: Andrew Morton <akpm@linux-foundation.org> Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
2007-10-16 01:28:26 -07:00
struct uvesafb_par *par = info->par;
int i = par->mode_idx;
#endif
uvesafb: the driver core uvesafb is an enhanced version of vesafb. It uses a userspace helper (v86d) to execute calls to the x86 Video BIOS functions. The driver is not limited to any specific arch and whether it works on a given arch or not depends on that arch being supported by the userspace daemon. It has been tested on x86_32 and x86_64. A single BIOS call is represented by an instance of the uvesafb_ktask structure. This structure contains a buffer, a completion struct and a uvesafb_task substructure, containing the values of the x86 registers, a flags field and a field indicating the length of the buffer. Whenever a BIOS call is made in the driver, uvesafb_exec() builds a message using the uvesafb_task substructure and the contents of the buffer. This message is then assigned a random ack number and sent to the userspace daemon using the connector interface. The message's sequence number is used as an index for the uvfb_tasks array, which provides a mapping from the messages coming from userspace to the in-kernel uvesafb_ktask structs. The userspace daemon performs the requested operation and sends a reply in the form of a uvesafb_task struct and, optionally, a buffer. The seq and ack numbers in the reply should be exactly the same as those in the request. Each message from userspace is processed by uvesafb_cn_callback() and after passing a few sanity checks leads to the completion of a BIOS call request. Signed-off-by: Michal Januszewski <spock@gentoo.org> Signed-off-by: Antonino Daplas <adaplas@gmail.com> Cc: Paul Mundt <lethal@linux-sh.org> Cc: Paulo Marques <pmarques@grupopie.com> Cc: "H. Peter Anvin" <hpa@zytor.com> Signed-off-by: Andrew Morton <akpm@linux-foundation.org> Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
2007-10-16 01:28:26 -07:00
int err = 0;
/*
* We support palette modifications for 8 bpp modes only, so
* there can never be more than 256 entries.
*/
if (start + count > 256)
return -EINVAL;
#ifdef CONFIG_X86
/* Use VGA registers if mode is VGA-compatible. */
if (i >= 0 && i < par->vbe_modes_cnt &&
par->vbe_modes[i].mode_attr & VBE_MODE_VGACOMPAT) {
for (i = 0; i < count; i++) {
outb_p(start + i, dac_reg);
outb_p(entries[i].red, dac_val);
outb_p(entries[i].green, dac_val);
outb_p(entries[i].blue, dac_val);
}
}
#ifdef CONFIG_X86_32
else if (par->pmi_setpal) {
__asm__ __volatile__(
"call *(%%esi)"
: /* no return value */
: "a" (0x4f09), /* EAX */
"b" (0), /* EBX */
"c" (count), /* ECX */
"d" (start), /* EDX */
"D" (entries), /* EDI */
"S" (&par->pmi_pal)); /* ESI */
}
#endif /* CONFIG_X86_32 */
else
#endif /* CONFIG_X86 */
{
task = uvesafb_prep();
if (!task)
return -ENOMEM;
task->t.regs.eax = 0x4f09;
task->t.regs.ebx = 0x0;
task->t.regs.ecx = count;
task->t.regs.edx = start;
task->t.flags = TF_BUF_ESDI;
task->t.buf_len = sizeof(struct uvesafb_pal_entry) * count;
task->buf = entries;
err = uvesafb_exec(task);
if ((task->t.regs.eax & 0xffff) != 0x004f)
err = 1;
uvesafb_free(task);
}
return err;
}
static int uvesafb_setcolreg(unsigned regno, unsigned red, unsigned green,
unsigned blue, unsigned transp,
struct fb_info *info)
{
struct uvesafb_pal_entry entry;
int shift = 16 - info->var.green.length;
int err = 0;
if (regno >= info->cmap.len)
return -EINVAL;
if (info->var.bits_per_pixel == 8) {
entry.red = red >> shift;
entry.green = green >> shift;
entry.blue = blue >> shift;
entry.pad = 0;
err = uvesafb_setpalette(&entry, 1, regno, info);
} else if (regno < 16) {
switch (info->var.bits_per_pixel) {
case 16:
if (info->var.red.offset == 10) {
/* 1:5:5:5 */
((u32 *) (info->pseudo_palette))[regno] =
((red & 0xf800) >> 1) |
((green & 0xf800) >> 6) |
((blue & 0xf800) >> 11);
} else {
/* 0:5:6:5 */
((u32 *) (info->pseudo_palette))[regno] =
((red & 0xf800) ) |
((green & 0xfc00) >> 5) |
((blue & 0xf800) >> 11);
}
break;
case 24:
case 32:
red >>= 8;
green >>= 8;
blue >>= 8;
((u32 *)(info->pseudo_palette))[regno] =
(red << info->var.red.offset) |
(green << info->var.green.offset) |
(blue << info->var.blue.offset);
break;
}
}
return err;
}
static int uvesafb_setcmap(struct fb_cmap *cmap, struct fb_info *info)
{
struct uvesafb_pal_entry *entries;
int shift = 16 - info->var.green.length;
int i, err = 0;
if (info->var.bits_per_pixel == 8) {
if (cmap->start + cmap->len > info->cmap.start +
info->cmap.len || cmap->start < info->cmap.start)
return -EINVAL;
entries = kmalloc(sizeof(*entries) * cmap->len, GFP_KERNEL);
if (!entries)
return -ENOMEM;
for (i = 0; i < cmap->len; i++) {
entries[i].red = cmap->red[i] >> shift;
entries[i].green = cmap->green[i] >> shift;
entries[i].blue = cmap->blue[i] >> shift;
entries[i].pad = 0;
}
err = uvesafb_setpalette(entries, cmap->len, cmap->start, info);
kfree(entries);
} else {
/*
* For modes with bpp > 8, we only set the pseudo palette in
* the fb_info struct. We rely on uvesafb_setcolreg to do all
* sanity checking.
*/
for (i = 0; i < cmap->len; i++) {
err |= uvesafb_setcolreg(cmap->start + i, cmap->red[i],
cmap->green[i], cmap->blue[i],
0, info);
}
}
return err;
}
static int uvesafb_pan_display(struct fb_var_screeninfo *var,
struct fb_info *info)
{
#ifdef CONFIG_X86_32
int offset;
struct uvesafb_par *par = info->par;
offset = (var->yoffset * info->fix.line_length + var->xoffset) / 4;
/*
* It turns out it's not the best idea to do panning via vm86,
* so we only allow it if we have a PMI.
*/
if (par->pmi_start) {
__asm__ __volatile__(
"call *(%%edi)"
: /* no return value */
: "a" (0x4f07), /* EAX */
"b" (0), /* EBX */
"c" (offset), /* ECX */
"d" (offset >> 16), /* EDX */
"D" (&par->pmi_start)); /* EDI */
}
#endif
return 0;
}
static int uvesafb_blank(int blank, struct fb_info *info)
{
struct uvesafb_ktask *task;
int err = 1;
#ifdef CONFIG_X86
struct uvesafb_par *par = info->par;
uvesafb: the driver core uvesafb is an enhanced version of vesafb. It uses a userspace helper (v86d) to execute calls to the x86 Video BIOS functions. The driver is not limited to any specific arch and whether it works on a given arch or not depends on that arch being supported by the userspace daemon. It has been tested on x86_32 and x86_64. A single BIOS call is represented by an instance of the uvesafb_ktask structure. This structure contains a buffer, a completion struct and a uvesafb_task substructure, containing the values of the x86 registers, a flags field and a field indicating the length of the buffer. Whenever a BIOS call is made in the driver, uvesafb_exec() builds a message using the uvesafb_task substructure and the contents of the buffer. This message is then assigned a random ack number and sent to the userspace daemon using the connector interface. The message's sequence number is used as an index for the uvfb_tasks array, which provides a mapping from the messages coming from userspace to the in-kernel uvesafb_ktask structs. The userspace daemon performs the requested operation and sends a reply in the form of a uvesafb_task struct and, optionally, a buffer. The seq and ack numbers in the reply should be exactly the same as those in the request. Each message from userspace is processed by uvesafb_cn_callback() and after passing a few sanity checks leads to the completion of a BIOS call request. Signed-off-by: Michal Januszewski <spock@gentoo.org> Signed-off-by: Antonino Daplas <adaplas@gmail.com> Cc: Paul Mundt <lethal@linux-sh.org> Cc: Paulo Marques <pmarques@grupopie.com> Cc: "H. Peter Anvin" <hpa@zytor.com> Signed-off-by: Andrew Morton <akpm@linux-foundation.org> Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
2007-10-16 01:28:26 -07:00
if (par->vbe_ib.capabilities & VBE_CAP_VGACOMPAT) {
int loop = 10000;
u8 seq = 0, crtc17 = 0;
if (blank == FB_BLANK_POWERDOWN) {
seq = 0x20;
crtc17 = 0x00;
err = 0;
} else {
seq = 0x00;
crtc17 = 0x80;
err = (blank == FB_BLANK_UNBLANK) ? 0 : -EINVAL;
}
vga_wseq(NULL, 0x00, 0x01);
seq |= vga_rseq(NULL, 0x01) & ~0x20;
vga_wseq(NULL, 0x00, seq);
crtc17 |= vga_rcrt(NULL, 0x17) & ~0x80;
while (loop--);
vga_wcrt(NULL, 0x17, crtc17);
vga_wseq(NULL, 0x00, 0x03);
} else
#endif /* CONFIG_X86 */
{
task = uvesafb_prep();
if (!task)
return -ENOMEM;
task->t.regs.eax = 0x4f10;
switch (blank) {
case FB_BLANK_UNBLANK:
task->t.regs.ebx = 0x0001;
break;
case FB_BLANK_NORMAL:
task->t.regs.ebx = 0x0101; /* standby */
break;
case FB_BLANK_POWERDOWN:
task->t.regs.ebx = 0x0401; /* powerdown */
break;
default:
goto out;
}
err = uvesafb_exec(task);
if (err || (task->t.regs.eax & 0xffff) != 0x004f)
err = 1;
out: uvesafb_free(task);
}
return err;
}
static int uvesafb_open(struct fb_info *info, int user)
{
struct uvesafb_par *par = info->par;
int cnt = atomic_read(&par->ref_count);
if (!cnt && par->vbe_state_size)
par->vbe_state_orig = uvesafb_vbe_state_save(par);
atomic_inc(&par->ref_count);
return 0;
}
static int uvesafb_release(struct fb_info *info, int user)
{
struct uvesafb_ktask *task = NULL;
struct uvesafb_par *par = info->par;
int cnt = atomic_read(&par->ref_count);
if (!cnt)
return -EINVAL;
if (cnt != 1)
goto out;
task = uvesafb_prep();
if (!task)
goto out;
/* First, try to set the standard 80x25 text mode. */
task->t.regs.eax = 0x0003;
uvesafb_exec(task);
/*
* Now try to restore whatever hardware state we might have
* saved when the fb device was first opened.
*/
uvesafb_vbe_state_restore(par, par->vbe_state_orig);
out:
atomic_dec(&par->ref_count);
if (task)
uvesafb_free(task);
return 0;
}
static int uvesafb_set_par(struct fb_info *info)
{
struct uvesafb_par *par = info->par;
struct uvesafb_ktask *task = NULL;
struct vbe_crtc_ib *crtc = NULL;
struct vbe_mode_ib *mode = NULL;
int i, err = 0, depth = info->var.bits_per_pixel;
if (depth > 8 && depth != 32)
depth = info->var.red.length + info->var.green.length +
info->var.blue.length;
i = uvesafb_vbe_find_mode(par, info->var.xres, info->var.yres, depth,
UVESAFB_EXACT_RES | UVESAFB_EXACT_DEPTH);
if (i >= 0)
mode = &par->vbe_modes[i];
else
return -EINVAL;
task = uvesafb_prep();
if (!task)
return -ENOMEM;
setmode:
task->t.regs.eax = 0x4f02;
task->t.regs.ebx = mode->mode_id | 0x4000; /* use LFB */
if (par->vbe_ib.vbe_version >= 0x0300 && !par->nocrtc &&
info->var.pixclock != 0) {
task->t.regs.ebx |= 0x0800; /* use CRTC data */
task->t.flags = TF_BUF_ESDI;
crtc = kzalloc(sizeof(struct vbe_crtc_ib), GFP_KERNEL);
if (!crtc) {
err = -ENOMEM;
goto out;
}
crtc->horiz_start = info->var.xres + info->var.right_margin;
crtc->horiz_end = crtc->horiz_start + info->var.hsync_len;
crtc->horiz_total = crtc->horiz_end + info->var.left_margin;
crtc->vert_start = info->var.yres + info->var.lower_margin;
crtc->vert_end = crtc->vert_start + info->var.vsync_len;
crtc->vert_total = crtc->vert_end + info->var.upper_margin;
crtc->pixel_clock = PICOS2KHZ(info->var.pixclock) * 1000;
crtc->refresh_rate = (u16)(100 * (crtc->pixel_clock /
(crtc->vert_total * crtc->horiz_total)));
if (info->var.vmode & FB_VMODE_DOUBLE)
crtc->flags |= 0x1;
if (info->var.vmode & FB_VMODE_INTERLACED)
crtc->flags |= 0x2;
if (!(info->var.sync & FB_SYNC_HOR_HIGH_ACT))
crtc->flags |= 0x4;
if (!(info->var.sync & FB_SYNC_VERT_HIGH_ACT))
crtc->flags |= 0x8;
memcpy(&par->crtc, crtc, sizeof(*crtc));
} else {
memset(&par->crtc, 0, sizeof(*crtc));
}
task->t.buf_len = sizeof(struct vbe_crtc_ib);
task->buf = &par->crtc;
err = uvesafb_exec(task);
if (err || (task->t.regs.eax & 0xffff) != 0x004f) {
/*
* The mode switch might have failed because we tried to
* use our own timings. Try again with the default timings.
*/
if (crtc != NULL) {
printk(KERN_WARNING "uvesafb: mode switch failed "
"(eax=0x%x, err=%d). Trying again with "
"default timings.\n", task->t.regs.eax, err);
uvesafb_reset(task);
kfree(crtc);
crtc = NULL;
info->var.pixclock = 0;
goto setmode;
} else {
printk(KERN_ERR "uvesafb: mode switch failed (eax="
"0x%x, err=%d)\n", task->t.regs.eax, err);
err = -EINVAL;
goto out;
}
}
par->mode_idx = i;
/* For 8bpp modes, always try to set the DAC to 8 bits. */
if (par->vbe_ib.capabilities & VBE_CAP_CAN_SWITCH_DAC &&
mode->bits_per_pixel <= 8) {
uvesafb_reset(task);
task->t.regs.eax = 0x4f08;
task->t.regs.ebx = 0x0800;
err = uvesafb_exec(task);
if (err || (task->t.regs.eax & 0xffff) != 0x004f ||
((task->t.regs.ebx & 0xff00) >> 8) != 8) {
/*
* We've failed to set the DAC palette format -
* time to correct var.
*/
info->var.red.length = 6;
info->var.green.length = 6;
info->var.blue.length = 6;
}
}
info->fix.visual = (info->var.bits_per_pixel == 8) ?
FB_VISUAL_PSEUDOCOLOR : FB_VISUAL_TRUECOLOR;
info->fix.line_length = mode->bytes_per_scan_line;
out: if (crtc != NULL)
kfree(crtc);
uvesafb_free(task);
return err;
}
static void uvesafb_check_limits(struct fb_var_screeninfo *var,
struct fb_info *info)
{
const struct fb_videomode *mode;
struct uvesafb_par *par = info->par;
/*
* If pixclock is set to 0, then we're using default BIOS timings
* and thus don't have to perform any checks here.
*/
if (!var->pixclock)
return;
if (par->vbe_ib.vbe_version < 0x0300) {
fb_get_mode(FB_VSYNCTIMINGS | FB_IGNOREMON, 60, var, info);
return;
}
if (!fb_validate_mode(var, info))
return;
mode = fb_find_best_mode(var, &info->modelist);
if (mode) {
if (mode->xres == var->xres && mode->yres == var->yres &&
!(mode->vmode & (FB_VMODE_INTERLACED | FB_VMODE_DOUBLE))) {
fb_videomode_to_var(var, mode);
return;
}
}
if (info->monspecs.gtf && !fb_get_mode(FB_MAXTIMINGS, 0, var, info))
return;
/* Use default refresh rate */
var->pixclock = 0;
}
static int uvesafb_check_var(struct fb_var_screeninfo *var,
struct fb_info *info)
{
struct uvesafb_par *par = info->par;
struct vbe_mode_ib *mode = NULL;
int match = -1;
int depth = var->red.length + var->green.length + var->blue.length;
/*
* Various apps will use bits_per_pixel to set the color depth,
* which is theoretically incorrect, but which we'll try to handle
* here.
*/
if (depth == 0 || abs(depth - var->bits_per_pixel) >= 8)
depth = var->bits_per_pixel;
match = uvesafb_vbe_find_mode(par, var->xres, var->yres, depth,
UVESAFB_EXACT_RES);
if (match == -1)
return -EINVAL;
mode = &par->vbe_modes[match];
uvesafb_setup_var(var, info, mode);
/*
* Check whether we have remapped enough memory for this mode.
* We might be called at an early stage, when we haven't remapped
* any memory yet, in which case we simply skip the check.
*/
if (var->yres * mode->bytes_per_scan_line > info->fix.smem_len
&& info->fix.smem_len)
return -EINVAL;
if ((var->vmode & FB_VMODE_DOUBLE) &&
!(par->vbe_modes[match].mode_attr & 0x100))
var->vmode &= ~FB_VMODE_DOUBLE;
if ((var->vmode & FB_VMODE_INTERLACED) &&
!(par->vbe_modes[match].mode_attr & 0x200))
var->vmode &= ~FB_VMODE_INTERLACED;
uvesafb_check_limits(var, info);
var->xres_virtual = var->xres;
var->yres_virtual = (par->ypan) ?
info->fix.smem_len / mode->bytes_per_scan_line :
var->yres;
return 0;
}
static void uvesafb_save_state(struct fb_info *info)
{
struct uvesafb_par *par = info->par;
if (par->vbe_state_saved)
kfree(par->vbe_state_saved);
par->vbe_state_saved = uvesafb_vbe_state_save(par);
}
static void uvesafb_restore_state(struct fb_info *info)
{
struct uvesafb_par *par = info->par;
uvesafb_vbe_state_restore(par, par->vbe_state_saved);
}
static struct fb_ops uvesafb_ops = {
.owner = THIS_MODULE,
.fb_open = uvesafb_open,
.fb_release = uvesafb_release,
.fb_setcolreg = uvesafb_setcolreg,
.fb_setcmap = uvesafb_setcmap,
.fb_pan_display = uvesafb_pan_display,
.fb_blank = uvesafb_blank,
.fb_fillrect = cfb_fillrect,
.fb_copyarea = cfb_copyarea,
.fb_imageblit = cfb_imageblit,
.fb_check_var = uvesafb_check_var,
.fb_set_par = uvesafb_set_par,
.fb_save_state = uvesafb_save_state,
.fb_restore_state = uvesafb_restore_state,
};
static void __devinit uvesafb_init_info(struct fb_info *info,
struct vbe_mode_ib *mode)
{
unsigned int size_vmode;
unsigned int size_remap;
unsigned int size_total;
struct uvesafb_par *par = info->par;
int i, h;
info->pseudo_palette = ((u8 *)info->par + sizeof(struct uvesafb_par));
info->fix = uvesafb_fix;
info->fix.ypanstep = par->ypan ? 1 : 0;
info->fix.ywrapstep = (par->ypan > 1) ? 1 : 0;
/*
* If we were unable to get the state buffer size, disable
* functions for saving and restoring the hardware state.
*/
if (par->vbe_state_size == 0) {
info->fbops->fb_save_state = NULL;
info->fbops->fb_restore_state = NULL;
}
/* Disable blanking if the user requested so. */
if (!blank)
info->fbops->fb_blank = NULL;
/*
* Find out how much IO memory is required for the mode with
* the highest resolution.
*/
size_remap = 0;
for (i = 0; i < par->vbe_modes_cnt; i++) {
h = par->vbe_modes[i].bytes_per_scan_line *
par->vbe_modes[i].y_res;
if (h > size_remap)
size_remap = h;
}
size_remap *= 2;
/*
* size_vmode -- that is the amount of memory needed for the
* used video mode, i.e. the minimum amount of
* memory we need.
*/
if (mode != NULL) {
size_vmode = info->var.yres * mode->bytes_per_scan_line;
} else {
size_vmode = info->var.yres * info->var.xres *
((info->var.bits_per_pixel + 7) >> 3);
}
/*
* size_total -- all video memory we have. Used for mtrr
* entries, resource allocation and bounds
* checking.
*/
size_total = par->vbe_ib.total_memory * 65536;
if (vram_total)
size_total = vram_total * 1024 * 1024;
if (size_total < size_vmode)
size_total = size_vmode;
/*
* size_remap -- the amount of video memory we are going to
* use for vesafb. With modern cards it is no
* option to simply use size_total as th
* wastes plenty of kernel address space.
*/
if (vram_remap)
size_remap = vram_remap * 1024 * 1024;
if (size_remap < size_vmode)
size_remap = size_vmode;
if (size_remap > size_total)
size_remap = size_total;
info->fix.smem_len = size_remap;
info->fix.smem_start = mode->phys_base_ptr;
/*
* We have to set yres_virtual here because when setup_var() was
* called, smem_len wasn't defined yet.
*/
info->var.yres_virtual = info->fix.smem_len /
mode->bytes_per_scan_line;
if (par->ypan && info->var.yres_virtual > info->var.yres) {
printk(KERN_INFO "uvesafb: scrolling: %s "
"using protected mode interface, "
"yres_virtual=%d\n",
(par->ypan > 1) ? "ywrap" : "ypan",
info->var.yres_virtual);
} else {
printk(KERN_INFO "uvesafb: scrolling: redraw\n");
info->var.yres_virtual = info->var.yres;
par->ypan = 0;
}
info->flags = FBINFO_FLAG_DEFAULT |
(par->ypan) ? FBINFO_HWACCEL_YPAN : 0;
if (!par->ypan)
info->fbops->fb_pan_display = NULL;
}
static void __devinit uvesafb_init_mtrr(struct fb_info *info)
uvesafb: the driver core uvesafb is an enhanced version of vesafb. It uses a userspace helper (v86d) to execute calls to the x86 Video BIOS functions. The driver is not limited to any specific arch and whether it works on a given arch or not depends on that arch being supported by the userspace daemon. It has been tested on x86_32 and x86_64. A single BIOS call is represented by an instance of the uvesafb_ktask structure. This structure contains a buffer, a completion struct and a uvesafb_task substructure, containing the values of the x86 registers, a flags field and a field indicating the length of the buffer. Whenever a BIOS call is made in the driver, uvesafb_exec() builds a message using the uvesafb_task substructure and the contents of the buffer. This message is then assigned a random ack number and sent to the userspace daemon using the connector interface. The message's sequence number is used as an index for the uvfb_tasks array, which provides a mapping from the messages coming from userspace to the in-kernel uvesafb_ktask structs. The userspace daemon performs the requested operation and sends a reply in the form of a uvesafb_task struct and, optionally, a buffer. The seq and ack numbers in the reply should be exactly the same as those in the request. Each message from userspace is processed by uvesafb_cn_callback() and after passing a few sanity checks leads to the completion of a BIOS call request. Signed-off-by: Michal Januszewski <spock@gentoo.org> Signed-off-by: Antonino Daplas <adaplas@gmail.com> Cc: Paul Mundt <lethal@linux-sh.org> Cc: Paulo Marques <pmarques@grupopie.com> Cc: "H. Peter Anvin" <hpa@zytor.com> Signed-off-by: Andrew Morton <akpm@linux-foundation.org> Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
2007-10-16 01:28:26 -07:00
{
#ifdef CONFIG_MTRR
if (mtrr && !(info->fix.smem_start & (PAGE_SIZE - 1))) {
int temp_size = info->fix.smem_len;
unsigned int type = 0;
switch (mtrr) {
case 1:
type = MTRR_TYPE_UNCACHABLE;
break;
case 2:
type = MTRR_TYPE_WRBACK;
break;
case 3:
type = MTRR_TYPE_WRCOMB;
break;
case 4:
type = MTRR_TYPE_WRTHROUGH;
break;
default:
type = 0;
break;
}
if (type) {
int rc;
/* Find the largest power-of-two */
while (temp_size & (temp_size - 1))
temp_size &= (temp_size - 1);
/* Try and find a power of two to add */
do {
rc = mtrr_add(info->fix.smem_start,
temp_size, type, 1);
temp_size >>= 1;
} while (temp_size >= PAGE_SIZE && rc == -EINVAL);
}
}
#endif /* CONFIG_MTRR */
}
static ssize_t uvesafb_show_vbe_ver(struct device *dev,
struct device_attribute *attr, char *buf)
{
struct fb_info *info = platform_get_drvdata(to_platform_device(dev));
struct uvesafb_par *par = info->par;
return snprintf(buf, PAGE_SIZE, "%.4x\n", par->vbe_ib.vbe_version);
}
static DEVICE_ATTR(vbe_version, S_IRUGO, uvesafb_show_vbe_ver, NULL);
static ssize_t uvesafb_show_vbe_modes(struct device *dev,
struct device_attribute *attr, char *buf)
{
struct fb_info *info = platform_get_drvdata(to_platform_device(dev));
struct uvesafb_par *par = info->par;
int ret = 0, i;
for (i = 0; i < par->vbe_modes_cnt && ret < PAGE_SIZE; i++) {
ret += snprintf(buf + ret, PAGE_SIZE - ret,
"%dx%d-%d, 0x%.4x\n",
par->vbe_modes[i].x_res, par->vbe_modes[i].y_res,
par->vbe_modes[i].depth, par->vbe_modes[i].mode_id);
}
return ret;
}
static DEVICE_ATTR(vbe_modes, S_IRUGO, uvesafb_show_vbe_modes, NULL);
static ssize_t uvesafb_show_vendor(struct device *dev,
struct device_attribute *attr, char *buf)
{
struct fb_info *info = platform_get_drvdata(to_platform_device(dev));
struct uvesafb_par *par = info->par;
if (par->vbe_ib.oem_vendor_name_ptr)
return snprintf(buf, PAGE_SIZE, "%s\n", (char *)
(&par->vbe_ib) + par->vbe_ib.oem_vendor_name_ptr);
else
return 0;
}
static DEVICE_ATTR(oem_vendor, S_IRUGO, uvesafb_show_vendor, NULL);
static ssize_t uvesafb_show_product_name(struct device *dev,
struct device_attribute *attr, char *buf)
{
struct fb_info *info = platform_get_drvdata(to_platform_device(dev));
struct uvesafb_par *par = info->par;
if (par->vbe_ib.oem_product_name_ptr)
return snprintf(buf, PAGE_SIZE, "%s\n", (char *)
(&par->vbe_ib) + par->vbe_ib.oem_product_name_ptr);
else
return 0;
}
static DEVICE_ATTR(oem_product_name, S_IRUGO, uvesafb_show_product_name, NULL);
static ssize_t uvesafb_show_product_rev(struct device *dev,
struct device_attribute *attr, char *buf)
{
struct fb_info *info = platform_get_drvdata(to_platform_device(dev));
struct uvesafb_par *par = info->par;
if (par->vbe_ib.oem_product_rev_ptr)
return snprintf(buf, PAGE_SIZE, "%s\n", (char *)
(&par->vbe_ib) + par->vbe_ib.oem_product_rev_ptr);
else
return 0;
}
static DEVICE_ATTR(oem_product_rev, S_IRUGO, uvesafb_show_product_rev, NULL);
static ssize_t uvesafb_show_oem_string(struct device *dev,
struct device_attribute *attr, char *buf)
{
struct fb_info *info = platform_get_drvdata(to_platform_device(dev));
struct uvesafb_par *par = info->par;
if (par->vbe_ib.oem_string_ptr)
return snprintf(buf, PAGE_SIZE, "%s\n",
(char *)(&par->vbe_ib) + par->vbe_ib.oem_string_ptr);
else
return 0;
}
static DEVICE_ATTR(oem_string, S_IRUGO, uvesafb_show_oem_string, NULL);
static ssize_t uvesafb_show_nocrtc(struct device *dev,
struct device_attribute *attr, char *buf)
{
struct fb_info *info = platform_get_drvdata(to_platform_device(dev));
struct uvesafb_par *par = info->par;
return snprintf(buf, PAGE_SIZE, "%d\n", par->nocrtc);
}
static ssize_t uvesafb_store_nocrtc(struct device *dev,
struct device_attribute *attr, const char *buf, size_t count)
{
struct fb_info *info = platform_get_drvdata(to_platform_device(dev));
struct uvesafb_par *par = info->par;
if (count > 0) {
if (buf[0] == '0')
par->nocrtc = 0;
else
par->nocrtc = 1;
}
return count;
}
static DEVICE_ATTR(nocrtc, S_IRUGO | S_IWUSR, uvesafb_show_nocrtc,
uvesafb_store_nocrtc);
static struct attribute *uvesafb_dev_attrs[] = {
&dev_attr_vbe_version.attr,
&dev_attr_vbe_modes.attr,
&dev_attr_oem_vendor.attr,
&dev_attr_oem_product_name.attr,
&dev_attr_oem_product_rev.attr,
&dev_attr_oem_string.attr,
&dev_attr_nocrtc.attr,
NULL,
};
static struct attribute_group uvesafb_dev_attgrp = {
.name = NULL,
.attrs = uvesafb_dev_attrs,
};
static int __devinit uvesafb_probe(struct platform_device *dev)
{
struct fb_info *info;
struct vbe_mode_ib *mode = NULL;
struct uvesafb_par *par;
int err = 0, i;
info = framebuffer_alloc(sizeof(*par) + sizeof(u32) * 256, &dev->dev);
if (!info)
return -ENOMEM;
par = info->par;
err = uvesafb_vbe_init(info);
if (err) {
printk(KERN_ERR "uvesafb: vbe_init() failed with %d\n", err);
goto out;
}
info->fbops = &uvesafb_ops;
i = uvesafb_vbe_init_mode(info);
if (i < 0) {
err = -EINVAL;
goto out;
} else {
mode = &par->vbe_modes[i];
}
if (fb_alloc_cmap(&info->cmap, 256, 0) < 0) {
err = -ENXIO;
goto out;
}
uvesafb_init_info(info, mode);
if (!request_mem_region(info->fix.smem_start, info->fix.smem_len,
"uvesafb")) {
printk(KERN_ERR "uvesafb: cannot reserve video memory at "
"0x%lx\n", info->fix.smem_start);
err = -EIO;
goto out_mode;
}
info->screen_base = ioremap(info->fix.smem_start, info->fix.smem_len);
if (!info->screen_base) {
printk(KERN_ERR
"uvesafb: abort, cannot ioremap 0x%x bytes of video "
"memory at 0x%lx\n",
info->fix.smem_len, info->fix.smem_start);
err = -EIO;
goto out_mem;
}
if (!request_region(0x3c0, 32, "uvesafb")) {
printk(KERN_ERR "uvesafb: request region 0x3c0-0x3e0 failed\n");
err = -EIO;
goto out_unmap;
}
uvesafb_init_mtrr(info);
platform_set_drvdata(dev, info);
if (register_framebuffer(info) < 0) {
printk(KERN_ERR
"uvesafb: failed to register framebuffer device\n");
err = -EINVAL;
goto out_reg;
}
printk(KERN_INFO "uvesafb: framebuffer at 0x%lx, mapped to 0x%p, "
"using %dk, total %dk\n", info->fix.smem_start,
info->screen_base, info->fix.smem_len/1024,
par->vbe_ib.total_memory * 64);
printk(KERN_INFO "fb%d: %s frame buffer device\n", info->node,
info->fix.id);
err = sysfs_create_group(&dev->dev.kobj, &uvesafb_dev_attgrp);
if (err != 0)
printk(KERN_WARNING "fb%d: failed to register attributes\n",
info->node);
return 0;
out_reg:
release_region(0x3c0, 32);
out_unmap:
iounmap(info->screen_base);
out_mem:
release_mem_region(info->fix.smem_start, info->fix.smem_len);
out_mode:
if (!list_empty(&info->modelist))
fb_destroy_modelist(&info->modelist);
fb_destroy_modedb(info->monspecs.modedb);
fb_dealloc_cmap(&info->cmap);
out:
if (par->vbe_modes)
kfree(par->vbe_modes);
framebuffer_release(info);
return err;
}
static int uvesafb_remove(struct platform_device *dev)
{
struct fb_info *info = platform_get_drvdata(dev);
if (info) {
struct uvesafb_par *par = info->par;
sysfs_remove_group(&dev->dev.kobj, &uvesafb_dev_attgrp);
unregister_framebuffer(info);
release_region(0x3c0, 32);
iounmap(info->screen_base);
release_mem_region(info->fix.smem_start, info->fix.smem_len);
fb_destroy_modedb(info->monspecs.modedb);
fb_dealloc_cmap(&info->cmap);
if (par) {
if (par->vbe_modes)
kfree(par->vbe_modes);
if (par->vbe_state_orig)
kfree(par->vbe_state_orig);
if (par->vbe_state_saved)
kfree(par->vbe_state_saved);
}
framebuffer_release(info);
}
return 0;
}
static struct platform_driver uvesafb_driver = {
.probe = uvesafb_probe,
.remove = uvesafb_remove,
.driver = {
.name = "uvesafb",
},
};
static struct platform_device *uvesafb_device;
#ifndef MODULE
static int __devinit uvesafb_setup(char *options)
{
char *this_opt;
if (!options || !*options)
return 0;
while ((this_opt = strsep(&options, ",")) != NULL) {
if (!*this_opt) continue;
if (!strcmp(this_opt, "redraw"))
ypan = 0;
else if (!strcmp(this_opt, "ypan"))
ypan = 1;
else if (!strcmp(this_opt, "ywrap"))
ypan = 2;
else if (!strcmp(this_opt, "vgapal"))
pmi_setpal = 0;
else if (!strcmp(this_opt, "pmipal"))
pmi_setpal = 1;
else if (!strncmp(this_opt, "mtrr:", 5))
mtrr = simple_strtoul(this_opt+5, NULL, 0);
else if (!strcmp(this_opt, "nomtrr"))
mtrr = 0;
else if (!strcmp(this_opt, "nocrtc"))
nocrtc = 1;
else if (!strcmp(this_opt, "noedid"))
noedid = 1;
else if (!strcmp(this_opt, "noblank"))
blank = 0;
else if (!strncmp(this_opt, "vtotal:", 7))
vram_total = simple_strtoul(this_opt + 7, NULL, 0);
else if (!strncmp(this_opt, "vremap:", 7))
vram_remap = simple_strtoul(this_opt + 7, NULL, 0);
else if (!strncmp(this_opt, "maxhf:", 6))
maxhf = simple_strtoul(this_opt + 6, NULL, 0);
else if (!strncmp(this_opt, "maxvf:", 6))
maxvf = simple_strtoul(this_opt + 6, NULL, 0);
else if (!strncmp(this_opt, "maxclk:", 7))
maxclk = simple_strtoul(this_opt + 7, NULL, 0);
else if (!strncmp(this_opt, "vbemode:", 8))
vbemode = simple_strtoul(this_opt + 8, NULL, 0);
else if (this_opt[0] >= '0' && this_opt[0] <= '9') {
mode_option = this_opt;
} else {
printk(KERN_WARNING
"uvesafb: unrecognized option %s\n", this_opt);
}
}
return 0;
}
#endif /* !MODULE */
static ssize_t show_v86d(struct device_driver *dev, char *buf)
{
return snprintf(buf, PAGE_SIZE, "%s\n", v86d_path);
}
static ssize_t store_v86d(struct device_driver *dev, const char *buf,
size_t count)
{
strncpy(v86d_path, buf, PATH_MAX);
return count;
}
static DRIVER_ATTR(v86d, S_IRUGO | S_IWUSR, show_v86d, store_v86d);
static int __devinit uvesafb_init(void)
{
int err;
#ifndef MODULE
char *option = NULL;
if (fb_get_options("uvesafb", &option))
return -ENODEV;
uvesafb_setup(option);
#endif
err = cn_add_callback(&uvesafb_cn_id, "uvesafb", uvesafb_cn_callback);
if (err)
return err;
err = platform_driver_register(&uvesafb_driver);
if (!err) {
uvesafb_device = platform_device_alloc("uvesafb", 0);
if (uvesafb_device)
err = platform_device_add(uvesafb_device);
else
err = -ENOMEM;
if (err) {
platform_device_put(uvesafb_device);
platform_driver_unregister(&uvesafb_driver);
cn_del_callback(&uvesafb_cn_id);
return err;
}
err = driver_create_file(&uvesafb_driver.driver,
&driver_attr_v86d);
if (err) {
printk(KERN_WARNING "uvesafb: failed to register "
"attributes\n");
err = 0;
}
}
return err;
}
module_init(uvesafb_init);
static void __devexit uvesafb_exit(void)
{
struct uvesafb_ktask *task;
if (v86d_started) {
task = uvesafb_prep();
if (task) {
task->t.flags = TF_EXIT;
uvesafb_exec(task);
uvesafb_free(task);
}
}
cn_del_callback(&uvesafb_cn_id);
driver_remove_file(&uvesafb_driver.driver, &driver_attr_v86d);
platform_device_unregister(uvesafb_device);
platform_driver_unregister(&uvesafb_driver);
}
module_exit(uvesafb_exit);
static int param_get_scroll(char *buffer, struct kernel_param *kp)
uvesafb: the driver core uvesafb is an enhanced version of vesafb. It uses a userspace helper (v86d) to execute calls to the x86 Video BIOS functions. The driver is not limited to any specific arch and whether it works on a given arch or not depends on that arch being supported by the userspace daemon. It has been tested on x86_32 and x86_64. A single BIOS call is represented by an instance of the uvesafb_ktask structure. This structure contains a buffer, a completion struct and a uvesafb_task substructure, containing the values of the x86 registers, a flags field and a field indicating the length of the buffer. Whenever a BIOS call is made in the driver, uvesafb_exec() builds a message using the uvesafb_task substructure and the contents of the buffer. This message is then assigned a random ack number and sent to the userspace daemon using the connector interface. The message's sequence number is used as an index for the uvfb_tasks array, which provides a mapping from the messages coming from userspace to the in-kernel uvesafb_ktask structs. The userspace daemon performs the requested operation and sends a reply in the form of a uvesafb_task struct and, optionally, a buffer. The seq and ack numbers in the reply should be exactly the same as those in the request. Each message from userspace is processed by uvesafb_cn_callback() and after passing a few sanity checks leads to the completion of a BIOS call request. Signed-off-by: Michal Januszewski <spock@gentoo.org> Signed-off-by: Antonino Daplas <adaplas@gmail.com> Cc: Paul Mundt <lethal@linux-sh.org> Cc: Paulo Marques <pmarques@grupopie.com> Cc: "H. Peter Anvin" <hpa@zytor.com> Signed-off-by: Andrew Morton <akpm@linux-foundation.org> Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
2007-10-16 01:28:26 -07:00
{
return 0;
}
static int param_set_scroll(const char *val, struct kernel_param *kp)
uvesafb: the driver core uvesafb is an enhanced version of vesafb. It uses a userspace helper (v86d) to execute calls to the x86 Video BIOS functions. The driver is not limited to any specific arch and whether it works on a given arch or not depends on that arch being supported by the userspace daemon. It has been tested on x86_32 and x86_64. A single BIOS call is represented by an instance of the uvesafb_ktask structure. This structure contains a buffer, a completion struct and a uvesafb_task substructure, containing the values of the x86 registers, a flags field and a field indicating the length of the buffer. Whenever a BIOS call is made in the driver, uvesafb_exec() builds a message using the uvesafb_task substructure and the contents of the buffer. This message is then assigned a random ack number and sent to the userspace daemon using the connector interface. The message's sequence number is used as an index for the uvfb_tasks array, which provides a mapping from the messages coming from userspace to the in-kernel uvesafb_ktask structs. The userspace daemon performs the requested operation and sends a reply in the form of a uvesafb_task struct and, optionally, a buffer. The seq and ack numbers in the reply should be exactly the same as those in the request. Each message from userspace is processed by uvesafb_cn_callback() and after passing a few sanity checks leads to the completion of a BIOS call request. Signed-off-by: Michal Januszewski <spock@gentoo.org> Signed-off-by: Antonino Daplas <adaplas@gmail.com> Cc: Paul Mundt <lethal@linux-sh.org> Cc: Paulo Marques <pmarques@grupopie.com> Cc: "H. Peter Anvin" <hpa@zytor.com> Signed-off-by: Andrew Morton <akpm@linux-foundation.org> Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
2007-10-16 01:28:26 -07:00
{
ypan = 0;
if (!strcmp(val, "redraw"))
ypan = 0;
else if (!strcmp(val, "ypan"))
ypan = 1;
else if (!strcmp(val, "ywrap"))
ypan = 2;
return 0;
}
#define param_check_scroll(name, p) __param_check(name, p, void)
uvesafb: the driver core uvesafb is an enhanced version of vesafb. It uses a userspace helper (v86d) to execute calls to the x86 Video BIOS functions. The driver is not limited to any specific arch and whether it works on a given arch or not depends on that arch being supported by the userspace daemon. It has been tested on x86_32 and x86_64. A single BIOS call is represented by an instance of the uvesafb_ktask structure. This structure contains a buffer, a completion struct and a uvesafb_task substructure, containing the values of the x86 registers, a flags field and a field indicating the length of the buffer. Whenever a BIOS call is made in the driver, uvesafb_exec() builds a message using the uvesafb_task substructure and the contents of the buffer. This message is then assigned a random ack number and sent to the userspace daemon using the connector interface. The message's sequence number is used as an index for the uvfb_tasks array, which provides a mapping from the messages coming from userspace to the in-kernel uvesafb_ktask structs. The userspace daemon performs the requested operation and sends a reply in the form of a uvesafb_task struct and, optionally, a buffer. The seq and ack numbers in the reply should be exactly the same as those in the request. Each message from userspace is processed by uvesafb_cn_callback() and after passing a few sanity checks leads to the completion of a BIOS call request. Signed-off-by: Michal Januszewski <spock@gentoo.org> Signed-off-by: Antonino Daplas <adaplas@gmail.com> Cc: Paul Mundt <lethal@linux-sh.org> Cc: Paulo Marques <pmarques@grupopie.com> Cc: "H. Peter Anvin" <hpa@zytor.com> Signed-off-by: Andrew Morton <akpm@linux-foundation.org> Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
2007-10-16 01:28:26 -07:00
module_param_named(scroll, ypan, scroll, 0);
MODULE_PARM_DESC(scroll,
"Scrolling mode, set to 'redraw', 'ypan', or 'ywrap'");
uvesafb: the driver core uvesafb is an enhanced version of vesafb. It uses a userspace helper (v86d) to execute calls to the x86 Video BIOS functions. The driver is not limited to any specific arch and whether it works on a given arch or not depends on that arch being supported by the userspace daemon. It has been tested on x86_32 and x86_64. A single BIOS call is represented by an instance of the uvesafb_ktask structure. This structure contains a buffer, a completion struct and a uvesafb_task substructure, containing the values of the x86 registers, a flags field and a field indicating the length of the buffer. Whenever a BIOS call is made in the driver, uvesafb_exec() builds a message using the uvesafb_task substructure and the contents of the buffer. This message is then assigned a random ack number and sent to the userspace daemon using the connector interface. The message's sequence number is used as an index for the uvfb_tasks array, which provides a mapping from the messages coming from userspace to the in-kernel uvesafb_ktask structs. The userspace daemon performs the requested operation and sends a reply in the form of a uvesafb_task struct and, optionally, a buffer. The seq and ack numbers in the reply should be exactly the same as those in the request. Each message from userspace is processed by uvesafb_cn_callback() and after passing a few sanity checks leads to the completion of a BIOS call request. Signed-off-by: Michal Januszewski <spock@gentoo.org> Signed-off-by: Antonino Daplas <adaplas@gmail.com> Cc: Paul Mundt <lethal@linux-sh.org> Cc: Paulo Marques <pmarques@grupopie.com> Cc: "H. Peter Anvin" <hpa@zytor.com> Signed-off-by: Andrew Morton <akpm@linux-foundation.org> Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
2007-10-16 01:28:26 -07:00
module_param_named(vgapal, pmi_setpal, invbool, 0);
MODULE_PARM_DESC(vgapal, "Set palette using VGA registers");
module_param_named(pmipal, pmi_setpal, bool, 0);
MODULE_PARM_DESC(pmipal, "Set palette using PMI calls");
module_param(mtrr, uint, 0);
MODULE_PARM_DESC(mtrr,
"Memory Type Range Registers setting. Use 0 to disable.");
module_param(blank, bool, 0);
MODULE_PARM_DESC(blank, "Enable hardware blanking");
module_param(nocrtc, bool, 0);
MODULE_PARM_DESC(nocrtc, "Ignore CRTC timings when setting modes");
module_param(noedid, bool, 0);
MODULE_PARM_DESC(noedid,
"Ignore EDID-provided monitor limits when setting modes");
module_param(vram_remap, uint, 0);
MODULE_PARM_DESC(vram_remap, "Set amount of video memory to be used [MiB]");
module_param(vram_total, uint, 0);
MODULE_PARM_DESC(vram_total, "Set total amount of video memoery [MiB]");
module_param(maxclk, ushort, 0);
MODULE_PARM_DESC(maxclk, "Maximum pixelclock [MHz], overrides EDID data");
module_param(maxhf, ushort, 0);
MODULE_PARM_DESC(maxhf,
"Maximum horizontal frequency [kHz], overrides EDID data");
module_param(maxvf, ushort, 0);
MODULE_PARM_DESC(maxvf,
"Maximum vertical frequency [Hz], overrides EDID data");
module_param_named(mode, mode_option, charp, 0);
MODULE_PARM_DESC(mode,
"Specify initial video mode as \"<xres>x<yres>[-<bpp>][@<refresh>]\"");
module_param(vbemode, ushort, 0);
MODULE_PARM_DESC(vbemode,
"VBE mode number to set, overrides the 'mode' option");
module_param_string(v86d, v86d_path, PATH_MAX, 0660);
MODULE_PARM_DESC(v86d, "Path to the v86d userspace helper.");
MODULE_LICENSE("GPL");
MODULE_AUTHOR("Michal Januszewski <spock@gentoo.org>");
MODULE_DESCRIPTION("Framebuffer driver for VBE2.0+ compliant graphics boards");